Flow back jet pump

ABSTRACT

A jet pump assembly is adapted to be releasably attached to a tubular member of a tubular string in an oil well. The jet pump may be pumped out of the tubular string to the surface by a reverse flow of power fluid down the well between the tubular string and the casing of the well. Consequently the jet pump may be serviced or reconfigured to a direct pumping mode without the necessity of a wire line or other apparatus. A sensor for measuring downhole parameters such as temperature and pressure etc. is positioned within a cavity located in a lower portion of the jet pump so as to be removable from the well with the pump.

This application is a continuation of application Ser. No. 14/474,912 filed Sep. 2, 2014.

BACKGROUND OF INVENTION

1. Field of the Invention

This invention relates to jet pumps that are used to lift fluids such as water and oil from the interior of an oil well. Pumps of this type utilize a nozzle and a venturi tube to create a pressure drop which can draw fluid from a location in the well below the pump. The power fluid and produced fluid from the well are then comingled in a mixing tube and diffuser where the pressure is increased to a point where the power and produced fluids are forced to the surface of the well where the produced fluids can be separated.

2. Description of Related Art

Jet pumps as described above are known that include a subassembly of the pump to be circulated back to the surface for servicing for example, by reverse flow of the power fluid. In normal operation, power fluid under pressure is pumped down a tubular positioned within the well casing and the mixture of the power fluid and produced fluid is conveyed upwardly in the annulus between the tubular and the casing. To pump back certain subassemblies for service. for example, the power fluid is pumped down the annulus and forces the subassembly up through the tubular.

Also, jet pumps are known that can be operated in a direct flow or reverse flow configuration. The nozzle assembly can be retrieved at the surface and replaced by a reverse flow nozzle arrangement. In this configuration, it is necessary to provide a stop mechanism to prevent the nozzle assembly from being pumped back to the surface in the reverse flow position. The stop mechanism may include a plurality of dogs on the pump housing which extend into an annular pocket found on the interior surface of a sub that surrounds the pump housing. A conventional tool may be used to pivot the dogs out of the pocket when it is desired to remove the inner components of the jet pump.

However, the prior art does not include an entire jet pump assembly that can be installed in the reverse flow mode and subsequently removed from the tubular string without the use of a wire line.

BRIEF SUMMARY OF THE INVENTION

The invention disclosed and claimed herein is directed to a jet pump of the type discussed above that can be totally removed from the tubular string. The pump is releasably held in place for reverse flow operation and can be removed by a tool that can be pumped down to the pump without the use of a wireline.

The tool is adapted to release locking dogs attached to the pump assembly and at the same time to attach to a fishing neck at the top portion of the pump assembly. The tool includes seals that engage the interior surface of the tubular string to facilitate the pumping out of the entire pump assembly when desired. In this manner the entire pump assembly can be removed from the tubular string as a unit without the necessity of a wireline or work over rig.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING(S)

FIG. 1 is a cross-sectional view of the pump unit positioned within a tubular and in the reverse flow mode

FIG. 2 is a cross-sectional view of the nozzle and carrier assembly.

FIG. 3 is a view of the retrieving tool attached to an upper portion of the jet pump.

FIG. 4 is a cross-sectional view of the pump unit in a direct flow mode.

DETAILED DESCRIPTION OF THE INVENTION

Referring to FIG. 1 the jet pump assembly 10 according to an embodiment of the invention is positioned within an outer tubular member 11 having an upper end 12 and lower end 13 adapted to be connected to a tubular string which extends within the casing (not shown) of an oil/gas well. Outer tubular member 11 is generally of the same diameter of the tubular string such that an annual gap exists between the outer surface of the outer tubular member 11 and the casing of a well. The upper end 12 of tubular member 11 includes an annular shoulder 62 and an annular recess 61. Recess 61 receives a plurality of pivotably mounted dogs 15 pivoted at 67 that cooperate with shoulder 62 to normally prevent upward movement of the jet pump unit within tubular member 11 when the jet pump assembly is in the reverse flow mode as shown in FIG. 1.

The jet pump assembly includes a jet pump housing 16 having an upper portion 14, a middle portion 27 and a lower portion 25. Lower portion 25 includes a lateral, diverging port 24 which in the reverse flow mode shown in FIG. 1 acts as an inlet port. In the direct flow mode port 24 acts as an outlet port. A sensor 75 for sensing downhole parameters such as pressure and temperature etc. is attached to a bottom portion 17 of lower portion 25 of the jet pump housting within a cavity 74.

A carrier member 21 is positioned within jet pump housing 16 and provides support for a mixing tube 23 and a jet nozzle 32 as shown in FIG. 2. A plurality of apertures 33 are provided in the carrier member 21 adjacent jet nozzle 32.

In the configuration shown in FIG. 1, power fluid is pumped down the annulus between the casing and tubular string and enters the interior of tubular member 11 through a plurality of apertures 53 provided in middle portion 36 of tubular member. The power fluid then enters port 24 and converging passageway 51 of the carrier member. At this point the velocity of the power fluid is increased and the pressure is reduced as is well known in the art.

As the power fluid exits nozzle 32, a further pressure reduction occurs and formation fluid is drawn up through lower portion 17 of the jet pump housing 16. The produced fluid passes through apertures 33 from a chamber 28 and is subsequently mixed with the power fluid in mixing tube 23. From there the mixture expands in divergent passageway 52 where the velocity decreases and the pressure increases thus enabling the mixture of power fluid and produced fluid to flow upwardly to the well head.

Should it be desired to retrieve the entire jet pump assembly for example, in order to service the pump or to reconfigure it to operate in a direct mode with the power fluid pumped down the tubular string, the entire jet pump assembly can be pumped up without the need of a wire line in the following manner.

An attachment tool 80 as shown in FIG. 3 is pumped down to engage the jet pump assembly. Attachment tool 80 includes a cylindrical body portion 81 and a cylindrical rod 82 extending downwardly from body portion 81. Rod 82 engages dogs 15 to move them out of annular recess 61. At the same time, latches within body 81 of the tool engage fishing neck 71 of the jet pump housing and upper portion 14 in a manner known in the art.

Attachment tool 80 also includes a plurality of seal cups 83 which engage the inner surface of the tubular string. Thus after the dogs 15 have been moved out of annular recess 61 and fishing neck 71 has been engaged, the entire pump assembly including jet pump housing 16 and carrier 21 may be pumped up by fluid entering through port 24.

The pump may be reconfigured to a direct flow mode by repositioning the nozzle 32 and mixing tube 23 such that power fluid will pass down the tubular string to first enter the nozzle and then flow into the mixing tube 23 and diffuser 51 as shown in FIG. 4. A plurality of seals 76 are positioned between the pump housing and tubular 11.

An example of a well know attachment tool that may be utilized is the model BT “JDC” pulling tool made by Brace Tool located in Alice, Tex. It has been modified by inclusion of the seal cups 83 and an upper fishing neck 84.

Although the present invention has been described with respect to specific details, it is not intended that such details should be regarded as limitations on the scope of the invention, except to the extent that they are included in the accompanying claims. 

I claim:
 1. A jet pump adapted to be releasably positioned within a tubular member comprising: a jet pump housing having upper and lower ends, a carrier member positioned within the jet pump housing, the carrier supporting a nozzle member, a mixing tube and a diffuser, a fluid port located in a wall of the jet pump housing, at least one inlet in the carrier member located proximate to the nozzle; a latching mechanism located at an upper end of the jet pump housing, the latching mechanism adapted to be releasably attached to an upper portion of the tubular member, and an attachment tool connectable to the upper end of the jet pump housing, said attachment tool having upwardly and downwardly facing seal cups adapted to engage an inner surface of the tubular member, whereby said attachment tool may be pumped down the tubular member and become attached to the jet pump and then pumped back to a surface of a well with the jet pump attached to the attachment tool without the use of a wireline.
 2. The jet pump as claimed in claim 1 further including said tubular member surrounding the jet pump and a plurality of seals located between the jet pump and the tubular.
 3. The jet pump as claimed in claim 1 further including plurality of apertures through a side wall of the tubular member.
 4. (canceled)
 5. The jet pump as claimed in claim 1 wherein the latching mechanism includes a plurality of latching dogs pivotably connected to the upper end of the jet pump housing.
 6. The jet pump as claimed in claim 5 further including said tubular member surrounding the pump, the tubular member including an annular groove and the latching dogs are releasably positioned in the annular groove.
 7. The jet pump according to claim 1 further including a sensor located with the lower end of the jet pump housing.
 8. A jet pump adapted to be releasably positioned within a tubular member comprising: a jet pump housing having upper and lower ends, a carrier member positioned within the jet pump housing, the carrier supporting a nozzle member, a mixing tube and a diffuser, a fluid port located in a wall of the jet pump housing, at least one inlet in the carrier member located proximate to the nozzle; and a sensor located within a cavity in the lower end of the jet pump housing.
 9. The jet pump as claimed in claim 8 wherein the jet pump housing includes a cavity at a lower portion thereof and the sensor is positioned within said cavity.
 10. A method of removing a jet pump from a tubular string positioned within the casing of a well comprising; providing an attachment tool adapted to be pumped down the tubular string and adapted to be pumped up to a surface of the well without the use of a wireline, pumping the attachment tool down the tubular string to engage and attach to the jet pump, pumping the attachment tool and the jet pump to the surface of the well by pumping fluid in a downwardly direction between the tubular string and the well casing. 